doi: 1.2169/internalmedicine.497-17 http://internmed.jp CASE REPORT Successful Treatment Hemophagocytic Lymphohistiocytosis Associated with Low-risk Myelodysplastic Syndrome by Azacitidine Shinya Daitoku 1, Tomomi Aoyagi 2, Shinichiro Takao 2, Seiya Tada 2 and Mika Kuroiwa 1 Abstract: Hemophagocytic lymphohistiocytosis (HLH) is a life-threatening syndrome that occurs as a complication in many clinical settings. Malignancy-associated HLH develops in patients with hematopoietic neoplasms, particularly in those with lymphoma, and its development in those with myelodysplastic syndrome (MDS) is uncommon. We herein report a case HLH in a patient with low-risk MDS that was successfully treated with azacitidine. The prevalence immune abnormalities among MDS patients and the immune effects azacitidine have recently been elucidated, suggesting that MDS-associated HLH occurs as a result immune impairment, and azacitidine improves this condition by restoring the immune system. Key words: myelodysplastic syndrome, hemophagocytic lymphohistiocytosis, azacitidine () () Introduction Hemophagocytic lymphohistiocytosis (HLH) is a rare and life-threatening syndrome characterized by excessive cytokine release from activated macrophages and T cells and typically presents with a fever, pancytopenia, hepatosplenomegaly, liver dysfunction, and hyperferritinemia (1, 2). Primary HLH is hereditary immune dysregulation with impaired cytotoxic T lymphocyte (CTL) or natural killer (NK) cells (1, 3, 4), and secondary HLH occurs as a complication many clinical conditions, such as infection, autoimmune disease, immunodeficiency, and malignancy (1-3). Malignancy-associated HLH (M-HLH) develops in patients with hematopoietic neoplasms, particularly in those with lymphoma (2, 5), and its development in those with myelodysplastic syndrome (MDS) is uncommon; therefore, the underlying pathogenesis is poorly understood, and treatment strategies for this condition are not established. We herein report a case HLH in a patient with low-risk MDS that was successfully treated with azacitidine. Case Report A 68-year-old Japanese man was referred to our department with prolonged pancytopenia for over 2 years. A hematological examination revealed a white blood cell count 1,1/μL, hemoglobin concentration 1.5 g/dl, and platelet count 45,/μL. Bone marrow aspirate indicated trilineage dysplasia with no excess blasts (Fig. 1). A chromosomal analysis showed a normal karyotype. Based on these findings, we diagnosed him with MDS with multilineage dysplasia according to the International Prognosis Scoring System (IPSS) Int-1, WHO classification-based Prognosis Scoring System Intermediate, and Revised-IPSS Intermediate. We decided to wait and watch because the prognosis scoring systems that indicate a low risk and pancytopenia seem to plateau after two years. One month later, he developed sudden liver injury. A serum chemistry examination demonstrated elevation hepatic enzyme levels as follows: aspartate aminotransferase (AST) 217 U/L, alanine aminotransferase (ALT) 289 U/L, and lactate dehydrogenase (LDH) Department Hematology, National Hospital Organization Fukuoka Higashi Medical Center, Japan and Department Gastroenterology and Hepatology, National Hospital Organization Fukuoka Higashi Medical Center, Japan Received: November 8, 217; Accepted: March 4, 218; Advance Publication by J-STAGE: May 18, 218 Correspondence to Dr. Shinya Daitoku, daitokuji.nattou@gmail.com 1
A B C Figure 1. Bone marrow smear specimen showing the presence trilineage dysplasia. (a) multinucleated erythroblast, (b) pseudo-pelger-huët anomaly in neutrophil, (c) micromegakaryocyte. Figure 2. Bone marrow smear specimen showing hemophagocytic macrophages. 553 U/L. He also had extreme elevation serum ferritin at 24,316 ng/ml without red blood cell transfusion. In addition, he exhibited mild splenomegaly, slight elevation soluble interleukin 2 receptor alpha (sil-2rα) at 1,25 U/mL, and hypibrinogenemia at 121 mg/dl, but he was unexpectedly afebrile. These manifestations were indicative HLH; therefore, we re-examined the bone marrow, and found a small number hemophagocytic macrophages (Fig. 2). A liver biopsy specimen suggested non-alcoholic steatohepatitis (NASH), but activated macrophages engulfing erythrocytes, a typical finding HLH in the liver, were not observed, and perivascular lymphoid infiltration was mild. The reactivation Epstein-Barr virus, cytomegalovirus, and hepatitis B virus was not detected. Of the proposed HLH diagnostic criteria in 29 (2), our patient exhibited splenomegaly, cytopenia, hepatitis, hemophagocytosis, elevated ferritin, elevated sil-2rα, and hypibrinogenemia. However, it was difficult to judge whether the cytopenia was derived from MDS or HLH. Based on these findings, we suspected HLH, but we were unable to confirm the diagnosis. Furthermore, whether or not MDS was involved in the occurrence HLH-like manifestations at that time was unclear. One month after the onset the HLH-like manifestations, high-dose methylprednisolone ( mg for 3 days) was administered. He showed a slight reduction in serum AST, ALT, and LDH, but his liver dysfunction continued to progress, and the serum ferritin levels increased to 43,639 ng/ml (the clinical course is summarized in Figure 3). The usefulness highly elevated ferritin in the diagnosis 2
WBC [/ L] 9, 8, 7, 6, 5, 4, 3, 2, AST [U/L] ALT [U/L] LDH [U/L] 1,2 Dx MDS WBC Hb Plt Ferritin LDH ALT AST Dx HLH HD-mPSL PSL CsA Flare-up HLH 5-Aza Hb [g/dl] Plt [x1 4 / L] 2 15 1 5 Ferritin [ng/ml] 1, 1, 8 6 4 1 2 1 May June July Aug. Sept. Oct. Nov. Dec. Jan. Feb. Mar. Apr. May June July Aug. 1 Figure 3. The clinical course. Sequential changes in the blood cell count (upper line chart), and serum AST, ALT, LDH, and ferritin levels (lower line chart) are shown. Ferritin is presented on a logarithmic scale. The patient received two cycles HD-mPSL ( mg for 3 days), oral PSL (starting with 6 mg and tapered afterwards), oral CsA (starting with 5 mg and gradually increased up to 15 mg), and 5 cycles 5-Aza (75 mg per square meter body-surface area on 7 consecutive days every 4 weeks). Dx: diagnosis, MDS: myelodysplastic syndrome, HLH: hemophagocytic lymphohistiocytosis, HD-mPSL: high-dose methylprednisolone, PSL: prednisolone, CsA: cyclosporine A, 5-Aza: azacitidine, WBC: white blood cell, Hb: hemoglobin, Plt: platelet, AST: aspartate aminotransferase, ALT: alanine aminotransferase, LDH: lactate dehydrogenase. HLH has been reported (6). A maximum ferritin level over 1, ng/ml was found to have a specificity 96% for the diagnosis HLH. It was also shown that the rate change in ferritin between admission and the maximum level was also higher in patients with HLH. Our patient had a maximum ferritin level far above 1, ng/ml and the rate change in ferritin was 1,136 ng/ml/day. Based on these findings, we established a diagnosis HLH. Fourteen days after the initial treatment, the administration cyclosporine A (CsA) was started with upward titration. The serum AST, ALT, LDH, and ferritin levels gradually declined subsequently but did not recede to normal levels. Eight months later, he developed a slight flare-up HLH. NASH-like findings and a small number hemophagocytic macrophages were observed in the reexamination the liver biopsy and bone marrow aspiration, respectively. He received another high dose methylprednisolone, and the serum ferritin level decreased but only to slightly below 2, ng/ml, suggesting difficulty immunosuppressive treatment. We therefore hypothesized the involvement MDS in the pathogenesis HLH. Decitabine has been reported to be effective against acute myeloid leukemia (AML)-associated HLH (7); we therefore administered azacitidine (75 mg per square meter bodysurface area on 7 consecutive days every 4 weeks) at 1 month after the second corticosteroid treatment. The serum AST, ALT, and LDH levels started to decrease within 1 days, and pancytopenia and hyperferritinemia improved after one cycle azacitidine. Eventually, four cycles azacitidine caused the blood cell count, serum AST, ALT, LDH, and ferritin to reach almost normal levels. Discussion HLH can accompany diverse malignancies (2, 5). In the present case, a stable patient with low-risk MDS suddenly developed HLH. Repeated treatment with corticosteroids and immunosuppressants was insufficient, whereas the admini- 3
Table. The Percentage CD4-positive T Cells, CD8-positive T Cells, and NK Cells in the Bone Marrow. The Numerical Values were Calculated by Flow Cytometry. The Percentage NK Cells was Calculated as the Difference between the CD2-positive Fraction and the CD3-positive Fraction. The Number NK Cells Markedly Increased at the Time HLH Flare-up and Decreased after Treatment with Azacitidine, Whereas the Numbers CD4- and CD8- positive T Cells Remained Almost Unchanged. Dx MDS Dx HLH Flare-up HLH Remission HLH CD4+T cells 3.12% 4.49% 4.98% 3.98% CD8+T cells 3.89% 5.4% 5.3% 5.11% NK cells 4.42% 5.81% 36.7% 7.4% CD: cluster differentiation, NK: natural killer, Dx: diagnosis, MDS: myelodysplastic syndrome, HLH: hemophagocytic lymphohistiocytosis stration azacitidine resulted in prompt improvement. We may draw two conclusions from the clinical course this patient. First, HLH can occur in low-risk MDS patients via a unique mechanism. In general, M-HLH is known to develop in two different clinical situations (5, 8). [1] HLH occurs as a manifestation with disease onset or relapse (malignancytriggered HLH). For this condition, the involvement cytokines secreted by malignant cells and viral infections is assumed. [2] HLH occurs during any phase chemotherapy (HLH during chemotherapy). In this setting, the infection virus, bacteria, or fungus caused by immunosuppression helps trigger HLH. In our case, the patient had pancytopenia for at least two years before the diagnosis, indicating the presence MDS for a long time before the occurrence HLH. In addition, he was completely naïve to chemotherapy. These findings suggest a distinctive pathogenesis MDSassociated HLH rather than conventional M-HLH. Immune dysregulation has been noted in several cell types derived from MDS patients, including T lymphocytes, NK cells, myeloid-derived suppressor cells, and mesenchymal stromal cells (9-11). For T lymphocytes, a variety abnormalities have been reported, including numerical anomalies, changes in the repertoire the T cell receptor, defective cytotoxicity, altered expression levels Foxp3 or chemokine receptors, and deficiency human telomerase reverse transcriptase. Furthermore, abnormalities in T cells can occur even if the clinical course MDS is stable (12). In NK cells from patients with MDS, decreased cytotoxicity, reduced levels perforin or granzyme B, and defective differentiation have been reported (13-15). To our knowledge, only one report has described MDS-associated HLH, and the patient with MDS-associated HLH had polyclonal expansion CD8- positive T lymphocytes in the bone marrow (16). In contrast, the proportion NK cells in our patient increased over time with serial bone marrow aspiration, especially during flareup, but decreased after azacitidine treatment (Table). These findings indicate the involvement an NK cell abnormality. A CTL or NK cell abnormality in the bone marrow was likely involved in the pathogenesis MDS-associated HLH. In primary HLH, the decreased activity CTL or NK cells constitutes the basis the pathogenesis (1, 3, 4). These data suggest that MDS-associated HLH occurs via a mechanism similar to that primary HLH rather than conventional M- HLH. Second, azacitidine is effective against MDS-associated HLH. In general, treatment for primary HLH is performed according to the HLH-24 protocol (17), and treatment for secondary HLH depends on the underlying conditions. For example, patients with lymphoma-associated HLH receive corticosteroids and CsA along with chemotherapy and ten allogeneic hematopoietic stem cell transplantation (3, 5, 8). However, a treatment strategy has not been established for HLH associated with other hematological malignancies, including AML and MDS. AML patients with HLH have a significantly higher mortality rate than those without HLH (18), and nearly all the case reports describing AML combined with HLH have had poor outcomes (19-21). To our knowledge, this is the first report describing the successful treatment MDS-associated HLH. In a previous report about an MDS patient with HLH, the administration corticosteroids and subsequent induction chemotherapy did not lead to improvement (16). The effectiveness decitabine for HLH associated with AML was reported previously (7). Decitabine is a hypo-methylating agent used for the treatment high-risk MDS and AML (22). Azacitidine is another hypo-methylating agent used for the treatment those diseases and is the only hypo-methylating agent available in Japan (22, 23). Azacitidine is known to have multiple effects, including cytotoxicity due to incorporation into DNA, re-activation silenced tumor suppressor genes via the inhibition DNA methyltransferase, and effects on the immune system (23). Anti-MDS activity is mainly produced by the first two effects. For MDS-associated HLH, the contribution the last effect should be considered based on the hypothesis that MDS-associated HLH occurs as a result immune dysregulation. The immune effects caused by azacitidine include the immune response caused by azacitidineinduced immune genes, the upregulation endogenous retroviruses in tumor cells, and the inhibition the nuclear factor kappa B pathway (23). In addition, azacitidine reverses aberrant T cell receptor repertoires observed in AML 4
and MDS patients (24). Azacitidine was also found to reverse the aberrant killer-cell immunoglobulin-like receptor repertoire and restore the impaired cytotoxic activity NK cells in MDS patients (25). These findings suggest that azacitidine is therapeutically effective for MDS-associated HLH not only due to cytotoxic effects against MDS clones but also due to the immune restoration CTLs and NK cells. In conclusion, the present case demonstrated the occurrence HLH in low-risk MDS and showed that azacitidine is effective against MDS-associated HLH. These findings suggest that HLH results from immune dysregulation and that azacitidine improves the disease by restoring the immune system in MDS patients. More clinical cases are needed to understand the pathogenesis and develop treatment strategies for MDS-associated HLH. The authors state that they have no Conflict Interest (COI). 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